def run(self):
super().run()
network = Cubic(shape=[self.topo.height,
self.topo.width,
self.topo.depth],
connectivity=self.topo.connectivity)
geometry = GenericGeometry(network=network,
pores=network.pores(),
throats=network.throats())
geometry.add_model(geometry=geometry, **self._pore_seed_model())
geometry.add_model(geometry=geometry, **self._pore_diameter_model())
geometry.add_model(geometry=geometry, **self._pore_volume_model())
geometry.add_model(geometry=geometry, **self._throat_seed_model())
geometry.add_model(geometry=geometry, **self._throat_diameter_model())
geometry.add_model(geometry=geometry, **self._throat_length_model())
geometry.add_model(geometry=geometry, **self._throat_volume_model())
invading_phase = GenericPhase(network=network, name='invading')
defending_phase = GenericPhase(network=network, name='defending')
if self.phs.type == 'custom':
invading_phase['pore.contact_angle'] = self.phs.contactAngle
invading_phase['pore.surface_tension'] = self.phs.surfaceTension
defending_phase['pore.contact_angle'] = self.phs.contactAngle
defending_phase['pore.surface_tension'] = self.phs.surfaceTension
invading_physics = GenericPhysics(network=network,
phase=invading_phase,
geometry=geometry)
defending_physics = GenericPhysics(network=network,
phase=defending_phase,
geometry=geometry)
invading_physics.add_model(**self._capillary_pressure_model())
defending_physics.add_model(**self._capillary_pressure_model())
algorithm = OP(network=network,
invading_phase=invading_phase,
defending_phase=defending_phase)
algorithm.run(inlets=network.pores('top'))
return {
'invasion_pressures': self._transform_data(algorithm).tolist(),
'pore_volumes': geometry['pore.volume'].tolist()
}
def run(params):
controller.clear()
topo = params['topology']
geo = params['geometry']
phs = params['phase']
phys = params['physics']
network = Cubic(shape=list(topo.dimensions.data.values()),
connectivity=topo.connectivity.data)
geometry = GenericGeometry(network=network,
pores=network.pores(),
throats=network.throats())
geometry.add_model(geometry=geometry, **_pore_seed_model(geo))
geometry.add_model(geometry=geometry, **_pore_diameter_model())
geometry.add_model(geometry=geometry, **_pore_volume_model())
geometry.add_model(geometry=geometry, **_throat_seed_model(geo))
geometry.add_model(geometry=geometry, **_throat_diameter_model())
geometry.add_model(geometry=geometry, **_throat_length_model())
geometry.add_model(geometry=geometry, **_throat_volume_model())
invading_phase = GenericPhase(network=network, name='invading')
invading_phase['pore.contact_angle'] = phs.contact_angle.data
invading_phase['pore.surface_tension'] = phs.surface_tension.data
invading_physics = GenericPhysics(network=network,
phase=invading_phase,
geometry=geometry)
invading_physics.add_model(**_capillary_pressure_model(phys))
algorithm = OrdinaryPercolation(network=network, invading_phase=invading_phase)
algorithm.run(inlets=network.pores('top'))
return {
'invasionPressure': _transform_data(algorithm).tolist(),
'poreDiameter': geometry['pore.diameter'].tolist(),
'throatDiameter': geometry['throat.diameter'].tolist(),
'throatLength': geometry['throat.length'].tolist()
}
